Ignition control system for an internal combustion engine

ABSTRACT

An ignition control system for an internal combustion engine which includes a microcomputer which operates to control the ignition timing in response to engine speed and engine temperature signals individually and in preselected combinations with an engine throttle or air flow signal during predetermined engine running conditions. These predetermined running conditions include low speed, warm up, overheat, cruising, and overspeed engine running conditions. The ignition control system is also capable of detecting and responding to abnormal combustion running conditions and setting an optimum spark advance during the starting of the engine.

BACKGROUND OF THE INVENTION

This invention relates generally to electronically controlled ignitionsystems for internal combustion engines, and in particular to anignition control system which is adapted to control the spark timing ofthe engine over a variety of engine running conditions.

Internal combustion engines have conventionally embodied mechanicallyoperated spark advance mechanisms for controlling the spark advance inrelation to throttle valve opening. Normally, the arrangement embodies amovably supported sensing device that is positioned in proximity to theengine crankcase and which generates a signal in response to thecrankshaft rotation for intiating spark timing. Either the sensingdevice or some other associated component is rotated relative to a fixedcomponent of the engine so as to change the spark timing. Normally, thespark timing is such that the spark is advanced to a predetermined angleat a given throttle valve opening and then is held at that angle.However, actual spark advance timing requirements are dependent uponother conditions than throttle openings and the previously proposedmechanically operated devies have not been able to produce the desiredspark timing under all running conditions.

Electronically controlled ignition systems have also been proposed forcontrolling the spark timing electronically. Although such devicesgenerally afford greater latitude in the timing control and the numberof conditions which they are responsive to, the previously proposedsystems have not been fully effective under all running conditions. Oneprior system which is principally directed to electronically advancingthe spark timing is disclosed in the assignee's copending U.S. patentapplication Ser. No. 525,316, entitled "Electronically ControlledIgnition Angle Advancing Device For Internal Combustion Engines", filedon Aug. 22, 1983, to Gohara, et al. This patent application is herebyincorporated by reference.

It is therefore a principal object of the present invention to providean improved ignition control system for an internal combustion engineand an improved method for electronically controlling the spark timingover a wide range of engine operating conditions.

It is another object of the present invention to provide an ignitioncontrol system which not only can advance and retard the spark timing,but is also capable of causing controlled engine misfires under theappropriate engine operating conditions.

It is a further object of the present invention to provide an ignitioncontrol system in which the spark timing is selectively a function ofthe engine temperature, the engine speed and the air flow to this engineinduction system.

It is an additional object of the present invention to provide anignition control system which is selectively responsive to abnormalcombustion running conditions so as to assure smooth engine operation.

It is yet another object of the present invention to provide an ignitioncontrol device which is capable of suppressing an overheat runningcondition of the engine by automatically and gradually reducing thespeed of the engine.

SUMMARY OF THE INVENTION

In order to achieve the foregoing objects, the present inventionprovides an ignition control device which generally includes means forproviding a speed signal indicative of the speed of the engine, meansfor providing a flow signal indicative of the air flow to the inductionsystem of the engine, and means for providing a temperature signalindicative of the temperature of the engine. Ignition timing means isthen provided for generating a spark timing signal in response to thespeed and temperature signals individually and in preselectedcombinations with the flow signal during predetermined runningconditions of the engine. These predetermined running conditionsinclude, for example, low speed, warm up, overheat, cruising, andoverspeed engine running conditions. The ignition control system alsoincludes means for detecting the crank angle of the engine, and meansfor generating an ignition signal in response to the crank angledetecting means and the spark timing signal during the running of theengine. The ignition signal generating means also includes means forgenerating an ignition signal having a predetermined advance during thestarting of the engine.

In accordance with another feature of the present invention, theignition control system as set forth in the preceding paragraph isgenerally responsive to the speed and flow signals to provide for anoptimum spark timing. However, when predetermined temperature and speedranges are exceeded or an abnormal combustion running conditiondetermined to exist, then the ignition control system will respond tothe specific engine running condition to provide an appropriate sparktiming which will compensate for this running condition.

Thus, one feature of the present invention is the capability ofdetecting and responding to an overheat running condition by a methodthat will initiate a misfire mode which is effective to cause a gradualdecrease in the speed of the engine. However, this misfire mode ispreferably initiated only if both the speed and flow signals haveexceeded individual predetermined threshold values. The misfire mode issubsequently discontinued when the flow signal has decreased below itspredetermined threshold value.

In accordance with another feature of the ingition control system as setforth in the first paragraph of this summary, means for sensing anddetermining the presence of an abnormal combustion running condition isalso included in the ignition control system. With such a provision, theignition control system has the capability of responding to an abnormalcombustion running condition by a method that will vary the spark timingsignal in a predetermined sequence when both the speed and flow signalshave exceeded individual predetermined threshold values. Thispredetermined sequence includes the steps of retarding the spark timingsignal in predetermined increments over predetermined time intervalsuntil the abnormal combustion running condition no longer exists, andthen readvancing the spark timing signal in a reverse order of thepredetermined increments over the predetermined time intervals.

Yet additional features of the present invention are adapted to beembodied in the ignition control system as set forth in the firstparagraph of this summary. One such feature is the capability ofdetecting and responding to a low speed running condition by providing aspark timing signal having a predetermined advance and holding thisspark timing signal at this advance for a predetermined number ofcrankshaft rotations. Another feature is the capability of detecting andresponding to an overspeed running condition by intermittentlyinterrupting the transmission of the ignition signal. A further featureis the capability of detecting and responding to an undesirable reverserunning condition by causing a misfire mode for all of the cylinders ofthe engine.

Additional advantages and features of the present invention will becomeapparent from a reading of the detailed description of the preferredembodiments which makes reference to the following set of drawings inwhich:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an end elevation view, with portions broken away, of an enginefor an outboard motor having an ignition system constructed inaccordance with an embodiment of the invention and operating inaccordance with a method of the invention.

FIG. 2 is a front elevation view of a portion of the outboard motorengine shown in FIG. 1.

FIG. 3 is a block diagram of the ignition system and particularly of theignition control system shown in FIG. 1.

FIG. 4 is an enlarged partial end elevation view, with portions brokenaway, of the ignition control system shown in FIG. 1.

FIG. 5 is an enlarged partial end elevation view, with portions brokenaway, of the outboard motor engine shown in FIG. 1, particularlyillustrating the power and pulse generating means of the ignitionsystem.

FIG. 6 is a graphical illustration of the magnet and coil constructionfor the pulse generating means of the ignition system shown in FIG. 5.

FIG. 7 is a graph of the pulse outputs from the pulse generating meansin relation to the pulses produced by the crank angle signal generatorshown in FIGS. 1 and 5.

FIG. 8 is an enlarged end elevation view of the throttle openingdetector and carburetor shown in FIG. 1.

FIG. 9 is a cross-sectional view of the throttle opening detector takenalong lines IX--IX of FIG. 8.

FIG. 10 is a flow chart illustrating the operation of the ignitioncontrol system for the starting of the outboard motor.

FIG. 11 is a flow chart which continues the flow chart of FIG. 10, andwhich illustrates the operation of the ignition control system for awarm up running condition.

FIG. 12 is a graph of the spark timing as a function of temperatureduring the warm up running condition.

FIG. 13 is a flow chart illustrating the operation of the ignitioncontrol system for a low speed running condition.

FIG. 14 is a flow chart illustrating the operation of the ignitioncontrol system for an overheat running condition.

FIG. 15 is a graph of the engine speed as a function of time during anoverheat running condition.

FIG. 16 is a flow chart illustrating the operation of the ignitioncontrol system for an abnormal combustion running condition.

FIG. 17 is a graph illustrating the sequence of varying the spark timingas a function of time during an abnormal combustion running condition.

FIG. 18 is a flow chart illustrating the operation of the ignitioncontrol system for an overspeed running condition.

FIG. 19 is a flow chart illustrating the operation of the ignitioncontrol system for a reverse running condition.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring first to FIGS. 1 and 2 of the drawings, an engine 11 for anoutboard motor is shown which has six cylinders in two rows that arearranged in the form of a "V" at a 90° bank angle. More specifically, afirst cylinder 11A and a second cylinder 11B are arranged to have V-likeform in combination. Similarly, the third cylinder 11C and the fourthcylinder 11D, and a fifth cylinder 11E and a sixth cylinder 11F arearranged, respectively, to provide V-like forms. The engine 11 has avertical crankshaft 12 to which pistons 14 are connected throughconnecting rods 13, such that the pistons are supported forreciprocation in their respective horizontal cylinders. Cylinder heads16 are fixed to their respective cylinders 11A-11F to form combustionchambers 15. Spark plugs 22A-22F are positioned in the cylinder heads16, there being one spark plug for each cylinder of the engine.

The engine 11 is of the two-cycle, crankcase compression type and isprovided with an induction system that suppies a fuel/air mixture tosealed crankcase chambers 19, each associated with a respective one ofthe cylinders. The induction system includes an air intake device 21that supplies air to a carburetor 20. The carburetor 20 has a throttlevalve 23 associated with each crankcase chamber 19 or with pairs of suchchambers 19, as is well known in this art. A reed type check valve 18 ispositioned in each carburetor induction passage or in the intakemanifold downstream of the throttle valve 23 for controlling the flow toa manifold passage 17 which, in turn, communicates with the respectivecrankcase chamber 19.

While the engine 11 is shown as a two-cycke V6 engine for an outboardmotor, it will become readily apparent to those skilled in the art thatthe invention may be susceptible for use with other types of internalcombustion engines and engines having other number of cylinders, even toan engine having only one cylinder.

FIGS. 1 and 2 also show that the engine is provided with an electronicignition controller 29 in accordance with the present invention. A blockdiagram of the controller 29 is shown in FIG. 3. The controller 29operates in response to the closing of a power switch 25 which isconnected to a battery 24. A starter switch 26 is also provided forenergizing a relay 27 which will cause a starter motor 28 to start theengine 11.

The heart of the controller 29 is a microcomputer (CPU) which providesan ignition timing means 30 for generating a spark timing signal. Thisspark timing signal controls the time at which an ignition signal istransmitted by the ignition signal generator 31. The ignition timingmeans 30 has been programmed to be selectively responsive to a varietyof input signals. These input signals are derived from five differentdetectors, namely pulser coils 32, throttle valve opening detector 34,temperature detector 35, overheat detector 36, and an abnormalcombustion or knock detector 37.

As will be more fully described below, a speed signal indicative of thespeed of the engine 11 is derived from the pulser coils 32, and a flowsignal indicative of the air flow to the induction system of the engineis derived from the throttle valve opening detector 34. Similarly, atemperature signal indicative of the temperature of the engine 11 isderived from both the temperature detector 35 and the overheat detector36. While it is preferred that separate detectors be used for thetemperature detector 35 and the overheat detector 36, it should beunderstood that a single detector could be employed in the appropriateapplication. As will be appreciated from the description below, theignition timing means is responsive to the speed andtemperature/overheat signals individually and in certain combinationswith the flow signal during various running conditions of the engine 11.

A crank angle signal generator 33 is also provided, which together withthe pulser coils 32 enables the controller 29 to determine therotational position of the crankshaft 12. This information is thenutilized by the ignition signal generator 31 to synchronize the timingof the ignition signal with the rotation of the crankshaft 12. Asillustrated in FIG. 3, a separate ignition signal is generated for eachof the six cylinders of the engine 11. These ignition signals aretransmitted to a capacitive discharge ignition (CDI) circuit or unit 38which is operative to fire the spark plugs 22A-22F in response to theappropriate ignition signal. The CDI circuit 38 may be of anyconventional design, such as illustrated in FIG. 4 of the Gohara, et alpatent application referred to above.

The controller 29 is also provided with a sampling period generator 30Ato provide a timing signal input to the ignition timing means 30.Additionally, a power supply or regulator circuit 39 is connected to thebattery 24 through the power switch 25 to drive each of the circuitsincluded in the controller 29.

As will be seen from FIG. 4, the controller 29 has a multiplicity ofelements or electronic parts arranged on a circuit board or substrate 41and accommodated by a case 42. These elements are held within the case42 while being enveloped by a resin filler 43 formed by the resinfilling the space in the case 42. The controller 29 has its major planecontaining the substrate 41 disposed substantially perpendicularly tothe principal direction of the vibration taking place in the engine,i.e. to the direction shown by line X--X in FIG. 1. Accordingly, amounting base 45 is secured to the central portion of the engine havingcylinders arranged in a form like V. A box-shaped mounting bracket 47 issecured to the mounting base 45 through an intermediary of a rubberdamper 46 by means of screws 47. The controller 29 is secured to themounting bracket 47 by means of screws 49 such that the substrate 41extends perpendicularly to the axis of the engine 11.

Referring to FIG. 5, a flywheel assembly is shown, which also forms aportion of a magneto generator. A rotor 50 is fixed at its base 51 tothe upper end of the crankshaft 12 of the engine 11 by means of asemi-circular key 52 and a nut 53. A permanent magnet 54 is attached tothe inner surface of the rotor 50. A reference numeral 55 designates apower generating coil. A plurality of coils 55 are arranged so as tooppose to the inner surface of the permanent magnet 54, and are fixed tolegs 56 provided on the engine 11.

A reference numeral 57 denotes an annular permanent magnet having anorth pole "N" and a south pole "S" which are arranged at 180° intervalsso as to diametrically oppose to each other around the base 51 of therotor 50. The engine 11 has three pulser coils 32A, 32B and 32C whichare arranged at 120° intervals and secured ot the inner surface of anannular holder 59. The annular holder 59 is in turn secured to supportbase 58 which is supported by the engine 11. The arrangement is suchthat one of three pulser coils 32A, 32B and 32C generates a pulse (i.e.,P₁ -P₆) at each 60° rotation of the crankshaft 12. As will be seen fromFIG. 6, pulses P₁ and P₂ (corresponding to the first and the fourthcylinders 11A and 11D) are generated in the (corresponding to the secondand fifth cylinders 11B and 11E). Similarly, pulses P₃ and P₆(corresponding to the third and sixth cylinders 11C and 11F) aregenerated in the pulser coil 32C. The timing at which the pulses P₁ toP₆ are produced is fixed to positions which are advanced from the topdead centers TDC of respective cylinders by starting ignition timingangles θ₀, e.g. by angle θ₀ before top dead center (BTDC).

A ring gear 60 adapted to receive the torque of the starter motor 28 atthe time of start up of the engine is fixed to the outer periphery ofthe rotor 50. The crank angle signal generator 33 is stationarilymounted on the engine 11 in a position which opposes the outerperipheral portion of the ring gear 60. The arrangement is such that, asthe crankshaft 12 rotates, pulses corresponding to the teeth of the ringgear 60 are generated by the crank angle signal generator 33.

The output pulses from the pulser coils 32 are encoded by an encoder 62through a wave shaping circuit 61 of the controller 29 as shown in FIG.3. These output pulses are successively transmitted in a formdistinguishable from one another to the preset counters 63 through theignition timing setting means 30. On the other hand, the output pulsesfrom the crank angle signal generator 33 are divided into pulses ofsmall width shown by Pc in FIG. 7 by a demultiplier circuit 64.

The pulser coils 32, the crank angle signal generator 33 and the presetcounter 63 constitute a crank angle detector in accordance with theinvention. The pulser coils 32 produce, with each rotation of thecrankshaft 12, the pulses corresponding in number to the number ofengine cylinders, at predetermined angular positions of the crankshaft12. Therefore, the pulser coils 32 function as the reference anglesignal generator for the crankshaft 12, so that the angular position ofthe crankshaft 12 can be detected by counting the number of pulsesissued by the crank angle signal generator 33 after the moment at whicha pulse is generated by a pulser coil 32.

The detection of the angular position of the crankshaft 12 may be madein a manner explained hereinunder with reference to FIG. 7. Pulse P₁from the pulser coil 32A represents a reference angle signal for thefirst engine cylinder 11A. Pulse P₁ occurs at a fixed advance angle θ₀before the top dead center (TDC) of the piston 14 in the cylinder 11A.When the pulse P₁ is generated, the pulses P_(c) produced by thecrankshaft angle signal generator 33 are counted by a preset counter 63in the ignition signal generator 31. Accordingly, the crank position isdetermined over an angular range of only 60°-θ in the six cylinderengine 11, since a new pulse is generated by the pulser coils 32 every60° of the crankshaft rotation. With this arrangement, it should beappreciated that the rotational position of the crankshaft can bedetermined with high precision by counting a relatively small number ofpulses.

The pulser coils 32 also function as an engine speed sensor for thecontroller 29. Namely, the pulser coils 32 produce pulses of a numbercorresponding to the number of cylinders in one full rotation of thecrankshaft 12. It is, therefore, possible to detect the revolution speedof the crankshaft 12, i.e. the engine speed, by counting the pulsesproduced by the pulser coil 32 in a unit time.

As will be seen from FIGS. 8 and 9, the throttle opening detector 34 hasa housing 67 constituted by a base portion 65 and a cap portion 66. Thehousing 67 is secured to a mounting bracket 69 by means of screws 68,while the mounting brackets 69 are fixed to the body of the carburetor20 by means of a screw 70. A contact 72 is fixed to the detection shaft71 of the throttle opening detector 34. As the detection shaft 71rotates, the contact 72 moves in sliding contact with the resistanceplate 73 so that the contact 72 and the resistance plate 73 incombination constitutes a potentiometer type transmitter. Namely, theopening degree of the throttle valve, i.e. the intake air flow rate tothe cylinders of the engine is detected in accordance with the positionof sliding contact between the contact 72 and the resistance plate 73.In this throttle opening detector 34, the detection shaft 71 isconnected directly to the throttle shaft 23A. Namely, in this throttleopening detector 34, both of the housing 67 and the detection shaft 71thereof are connected to the carburetor 20. Therefore, the housing 67and the detection shaft 71 vibrate always in the same vibration moderegardless of the vibration of the housing 67. Thus, relative movementbetween the housing 67 and the detection shaft 71 due to vibration iseliminated to avoid operation failure of the detector 34 attributable tothe vibration. The primary direction of the vibration of the engine 11coincides with the axis of the engine indicated by the line X--X shownin FIG. 1. This throttle opening detector 34, therefore, is arrangedsuch that the direction of axis of the detection shaft 71, which is lessresistant to the vibration, i.e. the direction of contact between thecontact 72 and the resistance plate 73, is substantially perpendicularto the primary direction of vibration occurring in the engine 11, sothat the detector 34 is protected from the vibration as its contact 72rotates. Rather than employ a device that is responsive to the positionof the throttle valve 23, an actual air flow sensing device of any knowntype, such as a hot wire anomometer, may be positioned directly in theinduction system.

The temperature detector 35 is constituted by, for example, a thermistorand is connected to a portion of the cylinder head 16 between the thirdcylinder 11C and the fifth cylinder 11E, so as to detect the temperatureof the engine 11 by way of the temperature of cooling water. However, itshould be appreciated that the temperature detector 35 couldalternatively be positioned so as to sense the temperature of some othercomponent of the engine. The results of detection by the throttledetector 34 and the temperature detector 35 are alternatinglytransmitted to the analog to digital (A/D) converter 75 through a buffer74. These results are then digitized in the A/D converter 75 and thentransmitted to the ignition timing means 30.

On the other hand, the overheat detector 36 is made of atemperature-sensitive switch of bimetal contact type, and is secured tothe cylinder head of each of the first cylinder 11A and the secondcylinder 11B. The overheat detector 36 detects the temperature of thecooling water in the cylinder head 16 and permits the transmission ofthe detected temperature above a predetermined threshold value to theignition timing means 30.

The knock detector 37 is of a vibration detection type employing apiezoelectric element or a magnetic strain type, and is secured to theportion of the cylinder head 16 between the fourth cylinder 11D and thesixth cylinder 11F. The knock detector 37 is adapted to detect vibrationin the engine exceeding a predetermined level to find any abnormalcombustion such as knocking, pre-ignition and so forth (referred to as"knock", hereinunder) and permits the transmission of the detectionresult to an ignition timing means 30. Alternatively, the knock detector37 may actually sense actual pressure in the combustion chamber. As iswell known, the pressure in the combustion chamber during knockingconditions is considerably higher than during normal combustionconditions. Alternatively, the knock detector 37 may sense otherabnormal combustion conditions as a preignition or run-on, all of whichare related to some extent to knocking although caused by slightlydifferent conditions. In each case, the condition is sensed by theprovision of a vibration or frequency that is considerably higher thanthat that occurs during normal combustion.

An explanation will now be made as to the practical procedure for thecontrol of the ignition performed by the controller 29. Referring firstto the operation of the controller 29 in the normal state of engine, theignition timing means 30 of the controller 29 beforehand stores in asuitable memory the optimum ignition timings with the parameters of theengine speed and the throttle opening as the intake air flow rate, inthe form of a map or a function. An example of such a map stored in theignition timing means 30 has been disclosed in the specification anddrawings of the Gohara, et al., patent application referred to above.Therefore, in the normal state of operation of the engine 11, theignition timing means 30 sets the ignition timing optimumly for thepresent state of engine operation from the above-mentioned map, inaccordance with the engine speed which is obtained through counting ofthe output pulses from the pulser coils 32 and the throttle opening,i.e. the intake air flow rate, detected by the throttle opening detector34. The thus determined optimum ignition timings are delivered to thepreset counters 63 of the ignition signal generators 31 of respectivecylinders.

On the other hand, the preset counters 63 constitute a part of the crankangle detector which detects the angular position of the crankshaft 12by counting the number of pulses generated in the crank angle signalgenerator 33 after the generation of the pulses from one of the pulsercoils 32.

A preset counter 63 as a part of the ignition signal generator 31delivers an ignition signal to the selector circuit 76 at a moment whichthe crank angle thus counted reaches the optimum ignition timingdelivered by the ignition timing means 30. The selector circuit 76receives a cylinder identification signal directly from the ignitiontiming means 30 concurrently with the ignition signal from the presetcounter 63. The ignition signal thus transmitted to the selector 76 isdelivered to the CDI circuit 38 for the appropriate cylinder through awave shaping circuit 77.

The operation of each CDI ignition means in the circuit 38 will now bedescribed. After commencing the charge of the ignition capacitor by avoltage generated by the power generating coil 55 of the magnet, thegate of a silicon controlled rectifier (SCR) is made to conduct by theignition signal current generated in the ignition signal generator 31.At the same time, the electrostatic charge stored in the ignitioncapacitor is rapidly applied to the primary side of an ignition coil,thereby producing at the secondary side of this coil a high voltage bywhich the spark plugs 22A to 22F of respective cylinders are caused todischarge. Thus, according to the advance angle control performed by thecontroller 29, the optimum ignition timing is read from a map stored inthe ignition timing means 30 so that the ignitions in respectivecylinders are made at predetermined optimum times.

An explanation will be made of the start up control performed by thecontroller 29. This start up control is performed by a start-up programshown in FIG. 10 which is written into and stored in the controller 29.After the closing of the power supply switch 25 in a step (1), as thestarter switch 26 is closed in a step (2), a judgment is made in a step(3) as to whether the closed state of the starter switch 26 ismaintained. If the answer is YES in the step (3), the operation of theselector circuit 76 is stopped by the operatin of the change-overcircuit 78 and a buffer 79 is started, so that the output from the waveshaping circuit 61, i.e the output signal which is fixed at a startingignition timing, (e.g. at BTDCθ₀), is transmitted to the wave shapingcircuit 77, thereby to control the CDI circuit 38 through the waveshaping circuit 77 such that the ignition takes place at BTDCθ₀. Thisoperation is conducted in a step (4). Then, the process returns to step(3) again. In the event that the answer is NO in the step (3), theoperation of the buffer 79 is stopped by the change-over circuit 78,while the selector circuit 76 is made to operate to make the ignitiontiming means 30 to operate such that the CDI unit 38 effects an ignitionat the optimum ignition timing which is in this case determined inaccordance with the output from the temperature detector 35. Thisoperation is made in a step (6).

According to the start control performed by the controller 29, theignition during the start up of the engine takes place at the timingoptimum for the start up, so that the start up of the engine isautomatically facilitated to insure a good start up of the engine.

An explanation will be made hereinunder as to the warm-up controlperformed by the controller 29 in connection with FIG. 11. This controlis conducted in accordance with the warming program stored in thecontroller 29 after the start up of the engine 11 by the start-upcontrol described above. The ignition timing means 30 beforehand storesthe warm-up ignition timing chart shown in FIG. 12, in which the axis ofabscisssa represents engine temperature "t" while the axis of ordinaterepresents the advance angle θ. Thus, when the engine is being warmed upafter the start-up and the engine temperature is still below atemperature t₂ °C. the optimum ignition timing is set at BTDCθ₁.Similarly, while the engine temperature is above t₂ °C. and below t₃ °C.the optimum ignition timing is selected to be, for example, BTDCθ₂.

Thus, the controller 29 delivers the output of the temperature detector35 to the ignition timing means 30 as described before in a step (6),and the ignition timing means makes a judgment as to whether the resultof detection is below t₂ °C. in a step (7). If the answer in the step(7) is YES, a judgment is made in a step (8) as to whether the advanceangle on the map under the present operating condition of engine isgreater than BTDCθ₁ in a step (8). If the answer in the step (8) is NO,the ignition timing means 30 selects the angle BTDCθ₁ as the optimumignition timing, so that the CDI circuit 38 is controlled through theignition signal generator 31 to effect the ignition at this timing in astep (9). Then, the process returns again to the step (6). In the casewhere the result of the judgment made in the step (8) is YES, theignition timing means 30 preferentially sets the advance angle inaccordance with the map as the optimum ignition timing, and controls theCDI circuit or unit 38 through the ignition signal generator 31 toeffect the ignition at this timing in a step (10).

In the event that the result of judgment in a step (7) is no, a judgmentis made in a step (11) as to whether the result of detection by thetemperature detector 35 is below t₃ °C. If the answer in the step (11)is YES, a judgment is made as to whether the advance angle on the mapunder this operating condition is greater than BTDCθ₂ in a step (12).When the answer obtained in the step (12) is NO, the ignition timingmeans 30 selects the BTDCθ₂ as the optimum ignition timing and controlsthe CDI unit 38 through the ignition signal generator 31 to effect theignition at this timing in a step (13). The process then returns to thestep (6). If the result of judgment in the step (12) is YES, theignition timing means 30 preferentially selects the advance angle on themap as the optimum ignition timing and controls the CDI unit 38 throughthe ignition signal generator 31 to effect the ignition at this timingin a step (14). To the contrary, if the answer obtained in the step (11)is NO, the ignition timing means 30 selects the advance angle on the mapas the optimum ignition timing, thereby to control the CDI unit 38through the ignition signal generator 31 to effect the ignition at thistiming in a step (15).

After the ignition control effected in the steps (10), (14) and (15),the process again returns to the step (6) so that the same controlprogram is executed repeatedly.

In the steps (8) and (12) of the warm-up control, when the advance angleon the map is greater than the advance angle in accordance with thewarm-up characteristics, the advance angle located on the map is usedpreferentially. There are two reasons for such preference. The firstreason is that, from the viewpoint of warm-up control, the greateradvance angle is preferred. The second reason is to avoid a significantreduction in the advance angle at this time which could cause asignificant decrease in the speed of the engine.

According to the warm-up control performed by the controller 29, itbecomes possible to effect an automatic control of the ignition timingduring warming up of the engine after the start up of the same such thatthe ignition is conducted at the timing optimum for the warming up ofthe engine without being accompanied by inadequate warming time anddegradation in the fuel consumption. It is thus possible to facilitatethe warming up of the engine and to make sure of the warming effect tostabilize the engine operation during the warming up of the engine.

An explanation will be made hereinunder as to the low speed controlperformed by the controller 29 during idling and trawling. The low speedcontrol is made in accordance with a low speed program as shown in FIG.13 stored in the controller 29. When the engine speed is lower than apredetermined low speed such as N₁ rpm, the advance angle BTDCθ₃ is usedas the optimum ignition timing. This advance angle is held or maintainedby the ignition timing means 30 until crankshaft 12 makes "n" rotations.More specifically, the controller 29 is adpated to process the frequencyof the output pulse from the pulser coils 32 by a frequency to voltage(F/V) converter 80 and produce an output voltage corresponding to theengine speed in a step (16). Then, in a step (17), a judgment is made bya low speed comparator circuit 81 as to whether the output voltage fromthe F/V converter 80 is below a reference voltage V₀₁ corresponding tothe engine speed N₁ rpm as set in a voltage setting means 82. If theanswer in the step (17) is YES, the ignition timing means 30 holdsBTDCθ₃ as the optimum ignition timing for a period corresponding to "n"rotations of the crankshaft 12 and controls the CDI unit 38 through theignition signal generator 31 to effect the ignition at this timing in astep (18). The process then returns to the step (16). To the contrary,when the answer of the judgment made in the step (17) is NO, theignition timing means 30 sets the advance angle located on the map asthe optimum ignition timing and controls the CDI unit 38 through theignition signal generator 31 to effect the ignition control in the step(19). The controller 29 then operates to return the process to the step(16) to execute this control program repeatedly.

In the low speed control explained hereinunder, the advance angle BTDCθ₃is maintained for the period corresponding to "n" rotations of thecrankshaft, in order to avoid unnecessary speed-up of the engine 11while effecting a smooth speed control.

According to this low speed control performed by the controller 29, whenthe speed of the engine 11 is increased to the preselected low speed,the ignition angle is automatically put ahead to permit the accelerationof the engine to avoid any stall of the engine. By repeating thisoperation, it is possible to stabilize the engine operation at this lowspeed. Namely, when the outboard engine 11 is operated in an idling ortrawling mode, it is possible to stabilize the engine operation at thedesired low speed with a small fuel consumption and low level of noise.For this reason, it becomes possible to keep the boat at a constantposition against movement by the tide.

An explanation will be made hereinunder as to the overheat suppressioncontrol method performed by the controller 29. This overheat suppressioncontrol is performed by an overheat suppressing program shown in FIG. 14and stored in the controller 29. When the engine temperature is higherthan the predetermined temperature t₄ ° C., and the throttle opening isgreater than a predetermined opening such as α₁, and the engine speed isgreater than a predetermined speed such as N₂ rpm, the ignition timingmeans 30 operates to successively bring some of the cylinders of theengine into a misfiring mode one by one at a predetermined timeinterval. This is achieved by preventing the ignition timing signals forsuch cylinders from being transmitted to the ignition signal generator31. FIG. 15 shows a diagram illustrating how the overheat control methodis conducted, in which the axis of abscissa represents time H while theaxis of ordinate indicates the engine speed N. Namely, in thisembodiment, in the engine 11 having six cylinders 11A to 11F, the sixthcylinder 11F, fifth cylinder 11E, third cylinder 11C and the secondcylinder 11B are successively brought into misfiring operation at a timeinterval H₁ which ranges between h₁ seconds and h₂ seconds, so that theengine finally operates with two cylinders, i.e. the first cylinder 11Aand the fourth cylinder 11D.

Thus, in this overheat suppressing control method, the controller 29 isadapted to deliver, in a step (20) the engine temperature detected bythe overheat detector 36, i.e. the temperature sensitive switch, to theignition timing means 30. Then, in a step (21), a judgment is made as towhether the detection result exceeds t₄ ° C. If the result of thejudgment made in the step (21) is NO, the process returns to the step(20). If the result is YES, a judgment is made as to whether thethrottle opening detected by the throttle detector 34 is greater thanα₁. If the result of judgment in the step (22) is NO, the process isreturned to the step (20). However, if the result of judgment is YES, ajudgment is made as to whether the engine speed measured by counting theoutput pulses from the pulser coils 32 is higher than N₂ rpm in a step(23). Then, if the result of the judgment in the step (23) is NO, thestep (23) is performed repeatedly. However, if the result of thejudgment is YES, the ignition timing means 30 executes a mis-firingcontrol shown in FIG. 15 in a step (24a) and holds the engine speed atN₂ rpm in a step (24b). Thereafter, a judgment is made as to whether thethrottle opening detected by the throttle opening detector 34 is lessthan α₁ in a step (24c). If the result of judgment in the step 24(c) isNO, the process returns to the step (24b) but, if the result is YES, theprocess is returned to the step (20) after dismissing the misfiringcontrol in a step (24d). When the answer of the judgment in the step(21) is YES, the controller 29 operates also to start a buzzer in a step(25) to warn the operator. In the following step (26), a judgment ismade as to whether the engine temperature as detected by the temperaturedetector 35 is below t₅ ° C. If the answer to the judgment made in thestep (26) is NO, the process is returned to the step (25) to continuethe warning by the buzzer. However, if the answer is YES, the buzzer isstopped in a step (27) and the process is returned to the step (20).

In the step (24c) of the overheat control program, a judgment is made asto whether the throttle opening exceeds α₁, for the reason explainedhereinbelow. When the engine temperature has come down as a result ofthe misfiring control executed in the steps (24a) and (24b), theigniting condition of the engine may be reset to the normal statewithout notice to the driver, thereby causing an unexpected accelerationof the engine. To avoid this, the misfiring control mode is notdismissed automatically even after the lowering of the enginetemperature. Rather, the misfiring control is dismissed through anintentional operation of the throttle by the operator.

On the other hand, in the step (23) of the overheat suppressing controlprogram, the engine speed is examined because it may not be possible tomaintain smooth engine operation with only two cylinders for an enginespeed below N₂ rpm.

Thus, in the overheat suppressing control performed by the controller29, when the engine temperature is raised to an abnormally high level,the buzzer goes off to warn the operator of the abnormal temperaturerise, while the engine speed is gradually decreased in a stepped mannerto prevent the overheat without stopping the engine. Thus, according tothe invention, some of cylinders of an engine having three or morecylinders are successively brought into misfiring mode at apredetermined time interval and the engine finally operates only withremainder or remainders of the cylinders, so that the occurrence of theoverheat of the engine is suppressed by decelerating the engine whileavoiding a drastic deceleration of the engine and the stop of watercooling or air cooling which would occur with a stall of the engine.

An explanation will now be made hereinunder as to the knock suppressingmethod performed by the controller 29. This knock suppression control isexecuted in accordance with the knock suppressing program shown in FIG.16 and stored in the controller 29. The ignition timing means 30 in thiscase operates to delay the ignition timing in a stepped manner upondetection of the abnormal combustion (knock) made by the knock detector37, and to hold the delay in each step. FIG. 17 is a diagram showing thestate of setting of the ignition timing, in which the axis of abscissarepresents the time H, while the axis of ordinate shows the angle θ ofadvance. Assuming that a knocking is detected at point A, the ignitionangle is delayed by an angle "a" degree at point B and this delay isheld for a predetermined period H₂ such as h₃ minutes. If the knock isfound after the expiration of the period between the points B and C, theignition timing is further delayed by "b" degrees at point D, and thisdelay is maintained for a period H₂. Thus, the amount of delay at thepoint D from the initial timing set at point A is expressed by (a+b)degrees. After the elapse of the period between points D and E, stepsreverse to those explained above are taken to resume the initialignition timing. If a knock is detected again in the period betweenpoints F and G, the ignition timing is delayed again by angle "b". Theamount of sum of angles "a" and "b" in FIG. 17 is selected to permitsufficient suppression of the knocking.

The process for knock suppressing control is as follows. In a step (28),the controller 29 inputs the result of detection by the knock detector37 to the ignition timing means 30 and a judgment is made in a step (29)as to whether there exists a knocking. If the result of judgment made inthe step (29) is NO, the process returns to step (28). However, if theresult of the judgment is YES, a judgment is made in a step (30) as towhether the engine speed, which is measured by counting the outputpulses from the pulser coils 32, is higher than N₃ rpm. If the result ofjudgment made in the step (30) is NO, the ignition timing means 30selects the advance angle read on the map as the optimum ignitiontiming, and controls the CDI unit 38 through the ignition timinggenerator 31 to effect the ignition at this timing in a step (31). Ifthe result of judgment made in the step (30) is YES, a judgment is madein a step (32) as to whether the throttle opening detected by thethrottle opening detector 34 is greater than α ₂ degree. If the answerto this judgment is NO, the ignition timing means 30 sets the advanceangle located on the map as the optimum ignition timing, and controlsthe CDI unit 38 through the ignition signal generator 31 to effect theignition at this timing in a step (33). To the contrary, if the resultof judgment made in the step (32) is YES, the ignition timing means 30delays the ignition timing by an angle "a" from the delayed timing whichhas been already obtained, and holds this delay for h₃ in a step (34).After the expiration of the period for holding this delay, the ignitiontiming means 30 makes a judgment as to whether there is a knock or notin a step (35). If the result of the judgment in the step (35) is NO,the ignition timing means 30 operates in a step (36) to resume theignition timing which has been obtained before the delay by angle "a"made in the step (34). If the result of judgment in the step (35) isYES, the ignition timing means 30 operates to further delay the ignitiontiming by angle "b" in addition to the delay by angle "a" attainedalready in the step (34). Thus, the ignition timing is delayed by angle(a+b) from the initial position and this delay is held for h₃ minutes ina step (37). Then, after elapse of the period for holding the delay inthe step (37), the ignition timing means 30 operates again to judgewhether there exists a knock in the engine in a step (36). If the resultof judgment made in a step (38) is YES, the process is returned to thestep (37) in which the delay by angle (a+b) is maintained again for theperiod of h₃ minutes. To the contrary, if the result of judgment made inthe step (38) is NO, the angle of delay "b" added in the step (37) isnullified so that the ignition timing resumes the delay angle "a" whichis maintained for h₃ minutes in a step (39). After the expiration ofthis period for holding this delay resumed in the step (39) is expired,the ignition timing means 30 further makes a judgment as to whetherthere is a knock in the engine in a step (40). If the answer to thisjudgment made in the step (40) is NO, the ignition timing means 30operates to resume the ignition timing which had been obtained beforethe delay by "a" attained in the step (39), and the process is thenreturned to the step (28). If the result of the answer to the judgmentmade in the step (40) is YES, the ignition timing means 30 adds thedelay angle "b" to the existing delay angle "a" attained in the step(39), and the process is returned to the step (37) for holding thisdelay (a+b) for a period of h₃ minutes. After the ignition control madein the steps (31) and (33), the process is returned to the step (28) andthe program described hereinbefore is conducted repeatedly.

In the step (30) of the knock suppressing control program explainedabove, a judgment is made as to whether the engine speed is higher thanN₃ rpm, because the engine operation at a speed less than N₃ rpm tendsto cause a stall of the engine operation and, hence, preferably beavoided. In addition, the reason why the judgment as to whether thethrottle opening is greater than α₂ is made in the step (32) of theknocking suppressing program is that the delay of the ignition anglewhen the opening degree of the throttle valve is less than α₂ couldcause a shock due to a rapid reduction of the engine speed.

According to the above-described knocking control performed by thecontroller 29, it is possible to delay the ignition time intentionallyfor a predetermined period of time when the knock takes place duringnormal operation of the engine 11 and to resume the ordinary ignitiontiming after elapse of a predetermined time. Since the delay of theignition timing is maintained for a predetermined time length, itbecomes possible to prevent undesirable frequent delays of the ignitiontiming from the normal timing and reset to the normal timing, which mayoccur when knocking is observed frequently within the predeterminedperiod mentioned above. It is, therefore, possible to avoid any toofrequent and rapid change in the engine speed and the speed of the boat.

In addition, since the delay is performed in a stepped manner, itbecomes possible to delay the ignition timing to such an extent as tosufficiently suppress the knocking, without being accompanied by a rapiddecrease in the engine speed and the speed of the boat. Generally,engines such as outboard engines are subjected to a large variety ofuses and operating conditions due to their natures, so that it is acommon measure to delay the maximum ignition advance angle from thedemanded advance angle, in order to avoid various undesirablecircumstances such as deposition of carbon on the combustion chamber andpiston, as well as knocking attributable to a mismatching of the sparkplug or use of a gas having low octane value. Thus, in conventionalengines, it is not possible to make full use of the performance of theengine. In contrast to the above, according to the knock suppressioncontrol of the invention, the engine is protected by avoiding a rapiddeceleration of the engine when a knock has taken place in the engine,whereas, when the engine is operated under a normal condition withoutany knock, it is possible to make full use of the performance of theengine.

Hereinunder, an explanation will be made as to an overspeed preventioncontrol method according to the present invention. This overspeedprevention control is conducted by an overspeed prevention program asshown in FIG. 18 stored in the controller 29. Namely, the controller 29is adapted to process the output pulse frequencies from the pulser coils32 corresponding to the first cylinder 11A, third cylinder 11C and thefifth cylinder 11E by means of an F/V converter 83, thereby to producean output voltage corresponding to the engine speed in a step (41).Then, in a step (42) an overspeed comparator circuit 84 judges whetherthe output voltage from the F/V converter mentioned above is below areference voltage V₀₂ corresponding to a predetermined speed, e.g. N₄rpm, set in the voltage setting means 85. If the answer to the judgmentin the step (42) is NO, the process returns to the step (41). To thecontrary, if the result of judgment in the step (42) is YES, anoverspeed comparator circuit 84 turns the transistor 86 ONintermittently. The emitter of the transistor 86 is connected to allsignal lines which transmits the ignition signals for respectivecylinders from the ignition signal generating means 31 to the CDI unit38, while the collector of the transistor 86 is grounded. Therefore, ifthe result of the judgment made in the step (42) is YES, the transistor86 is turned on intermittently. This will cause the ignition signalsfrom the ignition signal generating means 31 to be transmitted to theCDI unit only intermittently, so that the ignition takes placeintermittently in each cylinder thereby to prevent overspeed of theengine 11 in a step (43). The process then returns to the step (41).

Therefore, according to the overspeed prevention control performed bythe controller 29, it is possible to prevent abnormal increase of thespeed of the engine 11 under no load as in the case of the shifting toneutral gear condition, as well as other abnormal increases of the speedof the outboard engine to safely protect the engine against overspeed.

An explanation will be given hereinunder as to a reverse preventioncontrol performed by the controller 29. This reverse prevention controlis executed in accordance with a reversing prevention program shown inFIG. 19 written in the controller 29. During the operation of the enginestep (44), the ignition timing means 30 makes a judgment as to whetherthe output pulses P₁ to P₆ from the pulser coils 32 corresponding torespective cylinders are in correct order, i.e. P₁ P₂ P₃ P₄ P₅ P₆, in astep (45). If the answer to this judgment is NO, the ignition timingmeans 30 operates not to transmit the ignition timings for all cylindersto the ignition signal generating means 31 and effects a misfiringcontrol of the CDI unit 38 in a step (46). If the result of judgment inthe step (45) is YES, the ignition timing means 30 confirms that theengine 11 is operating in the forward direction in a step (47) and theprocess to the step (45) to continue ordinary ignition timing control.Therefore, according to the reverse prevention control by the controller29, it is possible to prevent accidental reversing of the engine whichcannot be perfectly avoided in 2 cycle engines.

It will be appreciated that the above disclosed embodiment is wellcalculated to achieve the aforementioned objectives of the presentinvention. In addition, it is evident that those skilled in the art,once given the benefit of the foregoing disclosure, may now makemodifications of the specific embodiment described herein withoutdeparting from the spirit of the present invention. Such modificationsare to be considered within the scope of the present invention which islimited solely by the scope and spirit of the appended claims.

What is claimed is:
 1. In an ignition system for an internal combustionengine, an ignition control system, comprising:means for providing aspeed signal indicative of the speed of said engine; means for providinga flow signal indicative of the air flow to the induction system of saidengine; means for providing a temperature signal indicative of thetemperature of said engine; means for detecting the crank angle of saidengine; ignition timing means for generating a spark timing signal whichis responsive to said speed and flow signals during predeterminedoperating conditions of said engine, and which is responsive only tosaid speed signal during a predetermined low speed running condition ofsaid engine, said low speed running condition representing an enginespeed below a predetermined low speed level, said ignition timing meansincluding means for detecting said low speed running condition and meansfor generating said spark timing signal with a value which represents apredetermined advance angle in response to the detection of said lowspeed running condition and maintaining said predetermined advance anglevalue for said spark timing signal for a predetermined number ofcrankshaft rotations of said engine; means for generating an ignitionsignal in response to said crank angle detecting means and said sparktiming signal during the running of said engine, including means forgenerating an ignition signal having a predetermined advance during thestarting of said engine.
 2. The ignition control system according toclaim 1, wherein said ignition timing means includes means forpreferentially generating said spark timing signal with a value which isresponsive to said temperature signal during a warming up runningcondition of said engine providing that the advance angle represented bysaid spark timing signal value which is responsive to said temperaturesignal is greater than the advance angle represented by said sparktiming signal value which is responsive to said speed and flow signals.3. The ignition control system according to claim 2, wherein saidignition timing means is responsive to said temperature signal duringsaid warming up running condition to generate a spark timing signalhaving a first value when the temperature of said engine is below afirst temperature level, and a second value when the temperature of saidengine is between said first temperature level and a second temperaturelevel, said first spark timing signal value representing a greateradvance angle than said second spark timing signal value.
 4. Theignition control system according to claim 1, further including meansfor determining an overspeed running condition from said speed signal,said overspeed running condition representing an engine speed above apredetermined high speed level.
 5. The ignition control system accordingto claim 4, further including means for intermittently interrupting thetransmission of said ignition signal in response to the detection ofsaid overspeed running condition until said overspeed running conditionhas terminated.
 6. The ignition control system according to claim 1,wherein said means for providing a speed signal and said means fordetecting the crank angle of said engine are responsive to a pulsegenerating means of said ignition system.
 7. The ignition control systemaccording to claim 6, wherein said means for providing a speed signalincludes means for encoding pulses from said pulse generating means. 8.The ignition control system according to claim 1, wherein said means forproviding a flow signal comprises a throttle opening detector whichoperates on an axis that is substantially perpendicular the primarydirection of vibration for said engine.
 9. The ignition control systemaccording to claim 1, wherein said engine is a multi-cylinder engine,and said ignition control system further includes means for detecting areverse running condition and for causing all of the cylinders of saidengine to cease fire in response to the detection of said reverserunning condition.
 10. A method of suppressing an overheat runningcondition for a multi-cylinder internal combustion engine, comprisingthe steps of:(a) measuring the temperature of said engine; (b)determining an overheat running condition from said temperaturemeasurement, said overheat running condition being determined by anengine temperature above a predetermined high temperature level; (c)providing a speed signal indicative of the speed of said engine; (d)providing a flow signal indicative of the air flow to the inductionsystem of said engine; and (e) initiating a cease fire mode in responseto the detection of said overheat running condition which is effectiveto cause a gradual decrease in the speed of said engine, said cease firemode including the step of causing at least one cylinder in said engineto intermittently cease firing by preventing the transmission of anignition timing signal, said cease fire mode only being initiated whensaid speed signal has exceeded a predetermined speed level and said flowsignal has exceeded a predetermined air flow level.
 11. The method asset forth in claim 10, including the steps of measuring the air flow tothe induction system of said engine, and discontinuing said misfire modewhen said air flow has decreased below a predetermined threshold value.12. The method as set forth in claim 11, further including the steps ofmeasuring the speed of said engine, and initiating said misfire modeonly if both the air flow and speed values have exceeded individualpredetermined threshold values.
 13. The method as set forth in claim 12,wherein said engine is a multi-cylinder engine, and said misfire modeincludes the step of causing preselected cylinders of said engine tomisfire in a predetermined sequence.
 14. In an ignition control systemfor an internal combustion system, means for detecting when thetemperature of said engine exceeds a predetermined high temperaturelevel, means for causing at least one cylinder of said engine tointermittently cease firing in response to the detection of said hightemperature level at a rate which will cause the speed of said engine todecrease to a predetermined low speed level, and means for maintainingsaid intermittent cease firing of said engine cylinder until thethrottle setting of said engine has been moved back to a settingcorresponding to said predetermined low speed value.
 15. The ignitioncontrol system according to claim 14, including means for providing aspeed signal indicative of the speed of said engine, and means forproviding a flow signal indicative of the air flow to the inductionsystem of said engine, said cease fire causing means including means forinitiating said cease firing only when said speed signal has exceeded apredetermined speed level and said flow signal has exceeded apredetermined air flow level.
 16. The ignition control system accordingto claim 15, wherein said maintaining means comprises means fordiscontinuing said cease firing only when said flow signal has decreasedbelow said predetermined air flow level.
 17. The ignition control systemaccording to claim 14, wherein said ignition timing means includes meansfor initiating a warning perceptible to the engine operator when saidtemperature signal has exceeded said predetermined high temperaturelevel.
 18. The ignition control system according to claim 14, whereinsaid engine is a multi-cylinder engine and said cease fire causing meansincludes means for causing preselected cylinders of said engine to ceasefiring in a predetermined sequence.